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This book considers the behavior of fluids in a low-gravity environment with special emphasis on application in PMD (propellant management device) systems . In the compensated gravity environment of a spacecraft, the hydrostatic pressure decreases to very low values depending on the residual acceleration, and surface tension forces become dominant. Consequently, surface tension can be used to transport and position liquids if the residual acceleration and the resulting hydrostatic pressure are small compared to the capillary pressure. One prominent application is the use of PMDs in surface-tension satellite tanks. PMDs must ensure that the tank outlet is covered with liquid whenever outflow is demanded. Furthermore, PMDs are used to ensure expulsion and refilling of tanks for liquids and gases for life support, reactants, and experiment supplies. Since most of the PMD designs are not testable on ground and thus rely on analytical or numerical concepts, this book treats three different flow problems with analytical, numerical and experimental means: the transient contour change between two static surface configurations (free surface oscillations), the capillary rise in tubes (capillary rise), and the flow through open capillary channels (choking). These problems are linked together by the same set of equations and boundary conditions which are necessary to model the fluid behavior, and by the same set of characteristic numbers.
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Auteur
Michael Dreyer, geb. 1959, studierte politische Wissenschaft, Geschichte und Volkskunde in Kiel. Seit 2005 hat er die Lehrstuhlvertretung Politische Theorie und Ideengeschichte an der Universität Jena inne; seine Forschungsschwerpunkte sind die Ideengeschichte des 19. Jahrhunderts (Deutschland, USA), Minderheiten und die Politische Theorie.
Texte du rabat
This book considers the behavior of fluids in a low-gravity environment with special emphasis on application in PMD (propellant management device) systems . In the compensated gravity environment of a spacecraft, the hydrostatic pressure decreases to very low values depending on the residual acceleration, and surface tension forces become dominant. Consequently, surface tension can be used to transport and position liquids if the residual acceleration and the resulting hydrostatic pressure are small compared to the capillary pressure. One prominent application is the use of PMDs in surface-tension satellite tanks. PMDs must ensure that the tank outlet is covered with liquid whenever outflow is demanded. Furthermore, PMDs are used to ensure expulsion and refilling of tanks for liquids and gases for life support, reactants, and experiment supplies. Since most of the PMD designs are not testable on ground and thus rely on analytical or numerical concepts, this book treats three different flow problems with analytical, numerical and experimental means: the transient contour change between two static surface configurations (free surface oscillations), the capillary rise in tubes (capillary rise), and the flow through open capillary channels (choking). These problems are linked together by the same set of equations and boundary conditions which are necessary to model the fluid behavior, and by the same set of characteristic numbers.
Résumé
This book considers the behavior of fluids in a low-gravity environment (e.g. spacecraft) with special emphasis on application in PMD (propellant management device) systems. Since PMD designs are not testable on ground and thus completely rely on analytical or numerical concepts, this book treats three different flow problems with analytical, numerical and experimental means. These problems are linked together by the same set of equations and boundary conditions.
Contenu
State of the Art.- Basic Equations and Dimensionless Numbers.- Orders of Magnitude of the Dimensionless Numbers.- Literature Review.- Surface Oscillations upon Step Reduction of the Bond Number.- Static Surface Shapes.- Scaling of the Dynamic Behavior.- Experiments on Surface Oscillations.- Numerical Calculations.- Conclusions.- Capillary Rise in Cylindrical Tubes.- Experiments on Capillary Rise.- Mathematical Model for the Capillary Rise.- Results and Discussion.- Summary.- Critical Velocities in Open Capillary Channel Flows.- and Background.- Mathematical Model for the Flow Between Parallel Plates.- Experimental Results.- Results and Discussion.- Perspectives.- Conclusion.- Future Projects.- Entrance Flow Problems.